Casio fx-CG100: The getkey command in Python

Casio fx-CG100: The getkey command in Python

The getkey command: A Demonstration

The fx-CG100 adds a command to its Casioplot module, the beloved getkey command. The getkey returns the key code of the last key pressed from the command’s execution. The getkey allows for custom keyboard, movement of characters, or easy input of menu choices.

The getkey code that is assigned to each key on the fx-CG100 is thankfully fairly simple: it is a combination of the row number and a column number. For instance, the key code 21 is assigned to the [SETTINGS] key while the key code 95 is assigned to the [EXE] key.

Some key codes include:

Left arrow (←)	23	Up arrow (↑)	14
OK key	24	Down arrow (↓)	34
Right arrow (→)	25	EXE	95
1 Key	81	2 Key	82
3 Key	83	4 Key	71
5 Key	72	6 Key	73
7 Key	61	8 Key	62
9 Key	63	0 Key	91

Other key assignments can be found in the manual under the getkey() command in the Casioplot section: https://support.casio.com/global/en/calc/manual/fx-CG100_1AUGRAPH_en/BONDSYlkjdoxxc.html#BONDSYhxeuohnh

Note that the [ ON ] and [ AC ] buttons have no key assigned to them and can not be used with the getkey command.

Example: Calculating Horsepower

The script, hp.py calculates horsepower by one of three sets of inputs:

Press [ 1 ] to input weight (pounds) and time (seconds).

Press [ 2 ] to input weight (pounds) and speed (mi/hr).

Press [ 3 ] to input RPM (revolutions per minute) and torque (foot-pounds).

Using Getkey for Menus

To set up the getkey, I first make a “choice variable”, such as ch, and set it to 0. The while loop contains the menu and does not end until the user presses [ 1 ], [ 2 ], or [ 3 ] (or [ AC ] to terminate the program).   

from casioplot import *

# setup

ch=0

# title screen

while ch==0:

  clear_screen()

  draw_string(0,0,"**HORSEPOWRER CALCULATOR**")

  draw_string(0,20,"**     Inputs Menu     **")

  draw_string(0,40,"1) weight, time",(192,0,0))

  draw_string(0,60,"2) weight, speed",(0,0,192))

  draw_string(0,80,"3) RPM, torque",(0,128,0))

  show_screen()

  k=getkey()

  if k==81:

    ch=1

  elif k==82:

    ch=2

  elif k==83:

    ch=3

  

# calculation

if ch==1:

  w=float(input("weight in lbs:  "))

  t=float(input("time in sec:  "))

  hp=w*(t/5.825)**(-3)

elif ch==2:

  w=float(input("weight in lbs:  "))

  s=float(input("speed in mph:  "))

  hp=w*(s/234)**3

elif ch==3:

  r=float(input("RPM:  "))

  t=float(input("torque (ft-lbs): "))

  hp=(r*t)/5252

clear_screen()

txt="{0:.5f} hp".format(hp)

draw_string(0,0,"Horsepower=")

draw_string(0,20,txt,(192,0,0))

draw_string(0,100,"Press AC to exit.",(0,128,128))

show_screen()

Notes: The getkey is meant to work with the Casioplot commands. Instead of the built-in print command, we use draw_string and show_screen commands to display output. The plus here is that we can have text in color. The show_screen is displayed until either the [ EXE ] or the back buttons is pressed.

The input command returns us to the Shell and is not part of the Casioplot commands.

Source for the Formulas Used: 

Inch Calculator “Engine Horsepower Calculator”. Calc Hub, LLC. 2025. https://www.inchcalculator.com/engine-horsepower-calculator/ Retrieved May 5, 2025.

Eddie

All original content copyright, © 2011-2025. Edward Shore. Unauthorized use and/or unauthorized distribution for commercial purposes without express and written permission from the author is strictly prohibited. This blog entry may be distributed for noncommercial purposes, provided that full credit is given to the author.

TI-84 Plus CE: Rafter Multipliers and Roof Area

TI-84 Plus CE: Rafter Multipliers and Roof Area

Introduction

Rafter multipliers are a quick way to calculate the area of a roof. All that is needed are three measurements:

(1) The width of a house

(2) The length of a house, including eaves and lengths of overhangs

(3) The pitch of the roof. The pitch the rise of the roof in inches over a run of 12 inches.

It is assumed that we have a simple roof and the area of the house is rectangular. Even in more complex cases, we can use the multipliers come up with a good approximation.

The area is approximated by:

roof area ≈ length * width * rafter factor

The common values are shown here:

Pitch (n in 12”)	Pitch (decimal – 3 places)	Rafter Factor (decimal -3 places)
2 in 12	0.167	1.014
3 in 12	0.250	1.031
4 in 12	0.333	1.054
5 in 12	0.417	1.083
6 in 12	0.500	1.118
7 in 12	0.583	1.158
8 in 12	0.667	1.202
9 in 12	0.750	1.250*
10 in 12	0.833	1.302
11 in 12	0.917	1.357
12 in 12	1.000	1.413
13 in 12	1.083	1.474
14 in 12	1.167	1.537
15 in 12	1.250	1.601
16 in 12	1.333	1.667
17 in 12	1.417	1.734
18 in 12	1.500	1.803
19 in 12	1.583	1.875
20 in 12	1.667	1.948
21 in 12	1.750	2.010
22 in 12	1.833	2.083
23 in 12	1.917	2.167

* This was erroneously labeled as 1.357 on the Dewalt Construction Math Quick Check guide (see Sources). Several sources correctly has the value of 1.250.

Curve Fitting

What if I can fit a formula to the above data?

I used a TI-84 Plus CE to assist me with this.

First, we’ll use the quadratic regression with the data from the above table:

y = a * x^2 + b * x + c

The resulting coefficients:

a = 0.1867080745

b = 0.2897396951

c = 0.938

r^2 = 0.9992015789

That’s a pretty good fit.

What about the square root fit:

y = √(a * x^2 + b)

If we square both sides, we get:

y^2 = a * x^2 + b

This equation takes somewhat the form of the linear regression.

Let z = x^2 and t = y^2, then:

z = a * t + b

Pitch (n in 12”)	X = Pitch (decimal – 3 places)	Z = X^2 (approximate)	Rafter Factor (decimal -3 places)	T = Y^2 (approximate)
2 in 12	0.167	0.0278	1.014	1.0282
3 in 12	0.250	0.0625	1.031	1.063
4 in 12	0.333	0.1111	1.054	1.1109
5 in 12	0.417	0.1736	1.083	1.1729
6 in 12	0.500	0.25	1.118	1.2499
7 in 12	0.583	0.3403	1.158	1.341
8 in 12	0.667	0.4444	1.202	1.4448
9 in 12	0.750	0.5625	1.250*	1.5625
10 in 12	0.833	0.6944	1.302	1.6952
11 in 12	0.917	0.8403	1.357	1.8414
12 in 12	1.000	1	1.413	1.9966
13 in 12	1.083	1.1736	1.474	2.1727
14 in 12	1.167	1.3611	1.537	2.3624
15 in 12	1.250	1.5625	1.601	2.5632
16 in 12	1.333	1.7778	1.667	2.7789
17 in 12	1.417	2.0069	1.734	3.0068
18 in 12	1.500	2.25	1.803	3.2508
19 in 12	1.583	2.5069	1.875	3.5156
20 in 12	1.667	2.7778	1.948	3.7947
21 in 12	1.750	3.0625	2.010	4.0401
22 in 12	1.833	3.3611	2.083	4.3389
23 in 12	1.917	3.6736	2.167	4.6959

Running the linear regression calculation with (z, t) we get:

a = 1.000120031

b = 1.00008392

r^2 = 0.9999332927

More accurate that the quadratic regression.

z = 1.000120031 * t + 1.00008392

y^2 = 1.000120031 * x^2 + 1.00008392

y = √(1.000120031 * x^2 + 1.00008392)

Analysis

I suspect that the exact formula for the rafter factor is:

rafter factor = √( pitch^2 + 1 ), pitch as a decimal

And the roof area is:

roof area = length * width * √( pitch^2 + 1 ) [ in inches ]

Roof area in square feet = Roof area in square inches / 144

Example

Area: length = 18 feet 6 inches, width = 20 feet, pitch = 7/12

In inches, length = 222 inches, width = 240 inches

roof area = 222 * 240 * √((7/12)^2 + 1) ≈ 61682.45131 in^2 ≈ 428.3503 ft^2

Sources

Prince, Christopher DeWALT Construction Math Quick Check: Extreme Duty Edition. Delmar, Cengage Learning: Cliffon Park, NY. 2010

Elliot. “Roof Area Calculator * Surface Area Multiplied by Pitch”. sktechandcalc.com. October 20, 2017. https://www.calculator.net/roofing-calculator.html?acarea=176&acareaunit=feet&roofpitch=4&angle=25&eaves=0&eavesunit=feet&price=&priceunit=feet&ctype=pitch&tp=ar&x=Calculate

calculator.net. “Roofing Calculator” 2008 – 2024. Retrieved November 4, 2024. https://www.calculator.net/roofing-calculator.html?acarea=176&acareaunit=feet&roofpitch=4&angle=25&eaves=0&eavesunit=feet&price=&priceunit=feet&ctype=pitch&tp=ar&x=Calculate

Eddie

All original content copyright, © 2011-2025. Edward Shore. Unauthorized use and/or unauthorized distribution for commercial purposes without express and written permission from the author is strictly prohibited. This blog entry may be distributed for noncommercial purposes, provided that full credit is given to the author.

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